The molecular basis for the specificity of fimE in the phase variation of type 1 fimbriae of Escherichia coli K-12

The expression of type 1 fimbriae in Escherichia coli is phase variable, with cells switching between fimbriate (ON) and afimbriate (OFF) phases. The phase variation is dependent on the orientation of a 314 bp DNA element (the switch) that undergoes DNA inversion. DNA inversion requires either fimB or fimE, site-specific recombinases that differ in both specificity and activity. Whereas fimB promotes recombination with little orientational bias, fimE promotes recombination in the ON-to-OFF direction exclusively. In wild-type cells, fimE activity predominates and, hence, most bacteria are afimbriate. Here, it is shown that fimE specificity is caused by two different, but complementary, mechanisms. First, FimE shows a strong preference for the switch in the ON orientation as a substrate for recombination. Differences in the nucleotide sequence of the recombinase binding sites is a key factor in determining FimE specificity, although one or more additional cis-active sites that flank the fim switch also appear to be involved. Secondly, the orientation of the switch controls fimE in cis, most probably to control recombinase expression.     

A tightly regulated inducible expression system utilizing the fim inversion recombination switch

The fim inversion system of Escherichia coli (E. coli) can behave as a unidirectional switch in an efficient manner. We have developed a new expression system for E. coli, comprising the arabinose-inducible fimE gene and the fim invertible DNA segment containing a constitutively active promoter. In this system, the target gene is cloned with the promoter in the OFF orientation, resulting in no transcribed product. When induced by arabinose, the active promoter is switched to the ON orientation via FimE-catalyzed DNA inversion, and the gene is expressed. Our expression system exhibited very tightly controlled basal expression and high induced expression, with simple induction by inexpensive arabinose. These characteristics make our system suitable for large-scale expression or for production of toxic proteins.     

Interaction of FimB and FimE with the fim switch that controls the phase variation of type 1 fimbriae in Escherichia coli K-12

The phase variation of type 1 fimbriae in Escherichia coli is associated with the site-specific inversion of a short DNA element. Recombination at fim requires fimB and fimE , and their products are considered to be the fim recombinases. In this study, FimB and FimE were overproduced and extracts containing the proteins were shown to (i) bind to and (ii) invert the fim switch in vitro . Phenanthroline-copper protection of DNA–protein complexes showed that both FimB and FimE bind to half-sites that flank, and overlap with, the left and right inverted repeats (IRL and IRR, respectively) of the fim switch. Alignment of the four half-sites identified a conserved 5'-CA doublet; mutation of these two bases lowers the affinity of binding of both FimB and FimE to the inverted repeats, and greatly diminishes inversion of the fim switch in vivo . The specificity of the fim recombinases observed in vivo (FimB switching in both directions; FimE switching from on-to-off only) was maintained in vitro Furthermore, the different binding affinities of FimB and FimE for the various half-site combinations suggests that the specificity of FimE could arise, in part, from the low affinity of FimE for IRL (off).     

Roles of fimB and fimE in site-specific DNA inversion associated with phase variation of type 1 fimbriae in Escherichia coli.

Evidence obtained with an improved in vivo assay of fimbrial phase variation in Escherichia coli supported a revised understanding of the roles of fimB and fimE in the site-specific DNA rearrangement with which they are associated. A previously proposed model argued that fimB and fimE play antagonistic, unidirectional roles in regulating the orientation of the invertible DNA element located immediately upstream of fimA, the gene encoding the major subunit of type 1 fimbriae. This conclusion, though, is based on an in vivo DNA inversion assay using recombinant plasmid substrates under conditions that, among other things, were incapable of detecting recombination of the fim invertible element from the on to the off orientation. Using a modified system that overcome this and several additional technical problems, we confirmed that fimB acts independently of fimE on the invertible element and that the additional presence of fimE results in the preferential rearrangement of the element to the off orientation. It is now demonstrated that fimE can act in the absence of fimB in this recombination to promote inversion primarily from on to off. In contrast to the previous studies, the effect of fimB on a substrate carrying the invertible element in the on orientation could be examined. It was found that fimB mediates DNA inversion from on to off, as well as from off to on, and that, contrary to prior interpretations, the fimB-associated inversion occurs with only minimal orientational preference to the on phase.     

DNA sequence heterogeneity in Fim tyrosine-integrase recombinase-binding elements and functional motif asymmetries determine the directionality of the fim genetic switch in Escherichia coli K-12

Phase-variable expression of type 1 fimbriae in Escherichia coli K-12 involves inversion by site-specific recombination of a 314 bp sequence containing the promoter for fim structural gene expression. The invertible sequence is flanked by 9 bp inverted repeats, and each repeat is in turn flanked by non-identical recombinase-binding elements (RBEs) to which the FimB or FimE site-specific recombinases bind. These proteins have distinct DNA inversion preferences: FimB inverts the switch in the ON-to-OFF and OFF-to-ON directions with similar efficiencies, whereas FimE inverts it predominantly in the ON-to-OFF direction. We have found that FimB and FimE invert the switch through a common mechanism. A genetic investigation involving base-by-base substitution combined with a biochemical study shows that the same DNA cleavage and religation sites are used within the 9 bp inverted repeats, and that each recombination involves a common 3 bp spacer region. A comprehensive programme of RBE exchanges and replacements reveals that FimB is much more tolerant of RBE sequence variation than FimE. The asymmetric location of conserved 5'-CA motifs at either side of each spacer region allows the inside and outside of the switch to be differentiated while the RBE sequence heterogeneity permits its ON and OFF forms to be distinguished by the recombinases.     

FimE-catalyzed off-to-on inversion of the type 1 fimbrial phase switch and insertion sequence recruitment in an Escherichia coli K-12 fimB strain

We have investigated the capacity of a well-defined Escherichia coli fimB strain, AAEC350 (a derivative of MG1655), to express type 1 fimbriae under various growth conditions. The expression of type 1 fimbriae is phase-variable due to the inversion of a 314-bp DNA segment. Two tyrosine recombinases, FimB and FimE, mediate the inversion of the phase switch. FimB can carry out recombination in both directions, whereas the current evidence suggests that FimE-catalyzed switching is on-to-off only. We show here that AAEC350 is in fact capable of off-to-on phase switching and type 1 fimbrial expression under aerobic static growth conditions. The phase switching is mediated by FimE, and allows emerging fimbriate AAEC350 to outgrow their non-fimbriate counterparts by pellicle formation. Following inversion of the phase switch, this element can remain phase-locked in the on orientation due to integration of insertion sequence elements, viz. IS1 or IS5, at various positions in either the fimE gene or the phase switch.     

Fifteen minutes of fim: control of type 1 pili expression in E. coli

Pili are used by Escherichia coli to attach to and invade mammalian tissues during host infection and colonization. Expression of type 1 pili, believed to act as virulence factors in urinary tract infections, is under control of the 'firm' genetic network. This network is able to sense the environment and actuate phase variation control. It is a prime exemplar of an integrative regulatory system because of its role in mediating a complex infection process, and because it instantiates a number of regulatory motifs, including DNA inversion and stochastic variation. With the help of a mathematical model, we explore the mechanisms and architecture of the fim network. We explain (1) basic network operation, including the roles of the recombinase and global regulatory protein concentrations, their DNA binding affinities, and their switching rates in observed phase variation behavior; (2) why there are two recombinases when one would seem to suffice; (3) the source of on-to-off switching specificity of FimE; (4) the role of fimE orientational control in switch dynamics; and (5) how temperature tuning of piliation is achieved. In the process, we identify a general regulatory motif that tunes phenotype to an environmental variable, and explain a number of apparent experimental inconsistencies.     

Integration host factor stimulates both FimB- and FimE-mediated site-specific DNA inversion that controls phase variation of type 1 fimbriae expression in Escherichia coli

The site-specific DNA inversion that controls phase variation of type 1 fimbriation in E. coli is catalysed by two recombinases, FimB and FimE. Efficient inversion by either recombinase also requires the leucine-responsive regulatory protein (Lrp). In addition, FimB recombination is stimulated by the integration host factor (IHF). The effect of IHF on FimE inversion has not previously been reported. Here it is shown that IHF stimulates FimE recombination; in strain MG1655, mutants containing lesions in either the α ( ihfA ) or β ( ihfB ) subunits of IHF show a marked decrease in both FimB- (100-fold) and FimE (15 000-fold)-promoted switching. IHF is shown to bind with high affinity to sites both adjacent to (site I) and within (site II) the fim invertible element. Furthermore, mutations in site I or site II that lower the affinity of IHF binding in vitro were found to lower the frequency of FimE and/or FimB recombination in vivo . Although site I and site II mutations in combination have an effect on FimB-promoted switching comparable to that of IHF knockout mutations (100-fold), the cis site mutations have a much less marked effect (100-fold) on FimE-promoted switching.     

Type 1 fimbriation and fimE mutants of Escherichia coli K-12.

We reexamined the influence of fimE, also referred to as hyp, on type 1 fimbriation in Escherichia coli K-12. We found that one strain used previously and extensively in the analysis of type 1 fimbriation, strain CSH50, is in fact a fimE mutant; the fimE gene of CSH50 contains a copy of the insertion sequence IS1. Using a recently described allelic exchange procedure, we transferred the fimE::IS1 allele from CSH50 to our present wild-type strain, MG1655. Characterization of this IS1-containing strain (AAEC137), together with another fimE mutant of MG1655 (AAEC143), led to two conclusions about the role of fimE. First, the formation of phase variant colony types, reported widely in strains of E. coli, depends on mutation of fimE, at least in K-12 strain MG1655. Here we showed that this phenomenon reflects the ability of fimE to stimulate the rapid inversion of the fim invertible element from on to off when the bacteria are grown on agar. Second, our analysis of fimE mutants, which is limited to chromosomal constructs, provided no evidence that they are hyperfimbriate. We believe that these results, which are at odds with a previous study using fim-containing multicopy plasmids, reflect differences in gene copy number.     

Type 1 fimbriation and phase switching in a natural Escherichia coli fimB null strain, Nissle 1917

Escherichia coli Nissle 1917 has been used as a probiotic against intestinal disorders for many decades. It is a good colonizer of the human gut and has been reported to be able to express type 1 fimbriae. Type 1 fimbriae are surface organelles which mediate alpha-D-mannose-sensitive binding to various host cell surfaces. The expression is phase variable, and two tyrosine recombinases, FimB and FimE, mediate the inversion of the fimbrial phase switch. Current evidence suggests that FimB can carry out recombination in both directions, whereas FimE-catalyzed switching is on to off only. We show here that under liquid shaking growth conditions, Nissle 1917 did not express type 1 fimbriae, due to a truncation of the fimB gene by an 1,885-bp insertion element. Despite its fimB null status, Nissle 1917 was still capable of off-to-on switching of the phase switch and expressing type 1 fimbriae when grown under static conditions. This phase switching was not catalyzed by FimE, by truncated FimB, or by information residing within the insertion element. No further copies of fimB seemed to be present on the chromosome of Nissle 1917, suggesting that another tyrosine recombinase in Nissle 1917 is responsible for the low-frequency off-to-on inversion of the phase switch that is strongly favored under static growth conditions. This is the first report documenting the non-FimB- or non-FimE-catalyzed inversion of the fim switch.     

Environmental regulation of the fim switch controlling type 1 fimbrial phase variation in Escherichia coli K-12: effects of temperature and media.

Expression of type 1 fimbriae in Escherichia coli K-12 is phase variable and associated with the inversion of a short DNA element (switch). The fim switch requires either fimB (on-to-off or off-to-on switching) or fimE (on-to-off switching only) and is affected by the global regulators leucine-responsive regulatory protein (Lrp), integration host factor (IHF), and H-NS. Here it is shown that switching frequencies are regulated by both temperature and media and that these effects appear to be independent. fimE-promoted on-to-off switching occurs far more rapidly than previously estimated (0.3 per cell per generation in defined rich medium at 37 degrees C) and faster at lower than at higher temperatures. In direct contrast, fimB-promoted switching increases with temperature, with optima between 37 and 41 degrees C. Switching promoted by both fimB and fimE is stimulated by aliphatic amino acids (alanine, isoleucine, leucine, and valine), and this stimulation requires lrp. Furthermore, lrp appears to differentially regulate fimB- and fimE-promoted switching in different media.     

Modulation of the sensitivity of FimB recombination to branched-chain amino acids and alanine in Escherichia coli K-12

Phase variation of type 1 fimbriae of Escherichia coli requires the site-specific recombination of a short invertible element. Inversion is catalyzed by FimB (switching in either direction) or FimE (inversion mainly from on to off) and is influenced by auxiliary factors integration host factor (IHF) and leucine-responsive regulatory protein (Lrp). These proteins bind to sites (IHF site II and Lrp sites 1 and 2) within the invertible element to stimulate recombination, presumably by bending the DNA to enhance synapses. Interaction of Lrp with a third site (site 3) cooperatively with sites 1 and 2 (termed complex 1) impedes recombination. Inversion is stimulated by the branched-chain amino acids (particularly leucine) and alanine, and according to a current model, the amino acids promote the selective loss of Lrp from site 3 (complex 2). Here we show that the central portion of the fim invertible element, situated between Lrp site 3 and IHF site II, is dispensable for FimB recombination but that this region is also required for full amino acid stimulation of inversion. Further work reveals that the region is likely to contain multiple regulatory elements. Lrp site 3 is shown to bind the regulatory protein with low affinity, and a mutation that enhances binding to this element is found both to diminish the stimulatory effects of IVLA on FimB recombination and to inhibit recombination in the absence of the amino acids. The results obtained emphasize the importance of Lrp site 3 as a control element but also highlight the complexity of the regulatory system that affects this site.